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Pharmacology Of Potential Anti-Tumour Agents: Iron Chelators Of The BpT Class
Funder
National Health and Medical Research Council
Funding Amount
$585,455.00
Summary
Pharmacology of Potential Anti-Tumour Agents: Iron Chelators of the BpT Class Cancer cells have a high iron requirement for DNA synthesis and many clinical trials showed Fe chelators are effective anti-cancer drugs. Their potential to act as anti-tumour agents has been confirmed by the entrance of Triapine into widespread NCI clinical trials. In this NHMRC Renewal, we will perform pharmacological and preclinical studies to promote the development of BpT chelators as novel anti-tumour agents.
Toxicological And Pre-clinical Assessment Of The Anti-cancer Compound Bp4eT
Funder
National Health and Medical Research Council
Funding Amount
$198,900.00
Summary
Cancer cells have a high iron requirement for DNA synthesis and many clinical trials showed Fe chelators are effective anti-cancer drugs. Their potential to act as anti-tumour agents has been confirmed by the entrance of Triapine into widespread NCI clinical trials. In this NHMRC Development Grant, we will perform toxicological studies to enable clinical trials of our most promising novel iron chelator to commence.
Iron is essential for the growth of all cells. Generally, cancer cells have a high iron requirement due to their rapid rate of proliferation. This makes them susceptible to the action of drugs called iron chelators that deplete cell iron. A wide variety of studies, including clinical trials in leukemia and neuroblastoma patients, have shown that the clinically used chelator, desferrioxamine (DFO), can have potent anti-tumour activity. Indeed, in an important clinical trial, a marked decrease in ....Iron is essential for the growth of all cells. Generally, cancer cells have a high iron requirement due to their rapid rate of proliferation. This makes them susceptible to the action of drugs called iron chelators that deplete cell iron. A wide variety of studies, including clinical trials in leukemia and neuroblastoma patients, have shown that the clinically used chelator, desferrioxamine (DFO), can have potent anti-tumour activity. Indeed, in an important clinical trial, a marked decrease in tumour burden was observed while there were no significant side effects, demonstrating an appreciable therapeutic index. However, DFO suffers from serious problems, including that it requires long infusions and does not readily penetrate cells. Further, in some cancer patients, DFO has shown little activity. Considering these results, we have developed a new group of chelators that show far greater activity than DFO at inhibiting cancer cell growth. These studies have been published in high quality journals such as BLOOD (Richardson et al. 1995, 1997, 1999) and form the basis for the current study. In this study we will examine how these iron-binding drugs work to inhibit the growth of cancer cells compared to their normal counterparts. These studies are important for the rational design of even more effective chelators. Recent studies in my lab have shown that our new chelators have far greater activity than a drug currently used to treat leukemia, known as hydroxyurea (HU). Our studies also show that the chelators act by a variety of mechanisms, explaining their greater activity than HU. Furthermore, we have shown that these chelators show significant anti-tumour activity in mice. The potential of this form of therapy has been confirmed by the entrance of the chelator, Triapine, into clinical trials (Vion Pharmaceuticals, USA). Our chelators are more effective than Triapine, thus, the present project is crucial for developing novel anti-tumour therapies.Read moreRead less
Targeted Cancer Chemotherapy: The Potential Of L-Nucleoside Prodrugs
Funder
National Health and Medical Research Council
Funding Amount
$204,750.00
Summary
The aim of this project to develop novel anti-cancer agents. We plan to use an unusual sugar (an L-nucleoside) that is not normally found in the body. This unusual sugar has the property of being taken up by tumour cells but not normal cells. We will use this unusual sugar to transport a toxic compound inside tumour cells so that the tumour cells are killed. In this way, we will preferentially kill tumour cells but leave normal cells unaffected. Hence we will produce an anti-cancer agent that is ....The aim of this project to develop novel anti-cancer agents. We plan to use an unusual sugar (an L-nucleoside) that is not normally found in the body. This unusual sugar has the property of being taken up by tumour cells but not normal cells. We will use this unusual sugar to transport a toxic compound inside tumour cells so that the tumour cells are killed. In this way, we will preferentially kill tumour cells but leave normal cells unaffected. Hence we will produce an anti-cancer agent that is highly effective at killing tumour cells but has few side-effects because it does not enter normal cells. Experimentally we will synthesise compounds where the L-nucleoside is attached to a toxic agent, fluorouridine or cisplatin analogues. We will then assess the ability of these novel compounds to kill tumour cells grown in the laboratory as well as tumours growing in mice. Additionally we will attempt to determine the mechanism of action of these drugs by investigating the following: the transport properties of the drugs; how and where these drugs damage DNA; the effect of the gene, p53, which can act to stop tumour growth. The ultimate aim of this project is to develop a novel class of anti-tumour agent based on L-nucleosides. These L-nucleoside analogues are expected to be more efficient at killing tumour cells but have fewer side effects.Read moreRead less